Cancer risk associated with chronic diseases and disease markers: prospective cohort study Huakang Tu, Chi Pang Wen,,3,4 Shan Pou Tsai, 5 Wong-Ho Chow, Christopher Wen, 6 Yuanqing Ye, Hua Zhao, Min Kuang Tsai, Maosheng Huang, Colin P Dinney, 7 Chwen Keng Tsao, 8 Xifeng Wu Department of Epidemiology, The University of Texas MD Anderson Cancer Center, Houston, TX 773, USA Institute of Population Health Sciences, National Health Research Institutes, Zhunan, Taiwan 3 Graduate Institute of Biomedical Sciences, College of Medicine, China Medical University, Taichung, Taiwan 4 Department of Medical Research, China Medical University Hospital, Taichung, Taiwan 5 MJ Health Research Foundation, Taipei, Taiwan 6 Radiology, Long Beach Veterans Administration Hospital, University of California at Irvine, CA, USA 7 Department of Urology, The University of Texas MD Anderson Cancer Center, Houston, TX, USA 8 MJ Health Management Institution, Taipei, Taiwan Correspondence to: X Wu xwu@mdanderson.org Additional material is published online only. To view please visit the journal online. Cite this as: BMJ 8;36:k34 http://dx.doi.org/.36/bmj.k34 Accepted: December 7 ABSTRACT OBJECTIVES To assess the independent and joint associations of major chronic diseases and disease markers with cancer risk and to explore the benefit of physical activity in reducing the cancer risk associated with chronic diseases and disease markers. DESIGN Prospective cohort study. SETTING Standard medical screening program in Taiwan. PARTICIPANTS 45 878 participants, for whom cardiovascular disease markers (blood pressure, total cholesterol, and heart rate), diabetes, chronic kidney disease markers (proteinuria and glomerular filtration rate), pulmonary disease, and gouty arthritis marker (uric acid) were measured or diagnosed according to standard methods, were followed for an average of 8.7 years. MAIN OUTCOME MEASURES Cancer incidence and cancer mortality. RESULTS A statistically significantly increased risk of incident cancer was observed for the eight diseases and markers individually (except blood pressure and pulmonary disease), with adjusted hazard ratios ranging from.7 to.44. All eight diseases and markers were statistically significantly associated with risk of cancer death, with adjusted hazard ratios ranging from. to.7. Chronic disease risk scores What is already known on this topic Studies have shown that certain chronic diseases (eg, diabetes and chronic kidney disease) may predispose to cancer Investigations generally assessed individual chronic diseases rather than combined Physical activity has been shown to reduce all cause mortality, but the role of physical activity in reducing the cancer risk associated with chronic diseases is unclear What this study adds A substantial cancer risk is associated with a combination of cardiovascular disease markers, diabetes, chronic kidney disease markers, pulmonary disease, and gouty arthritis marker These factors contribute to more than one fifth of incident cancers and more than one third of cancer deaths, comparable to the combined contribution of five lifestyle risk factors Furthermore, physical activity was associated with a nearly 4% reduction in the risk of cancer associated with chronic diseases or markers summarizing the eight diseases and markers were positively associated with cancer risk in a doseresponse manner, with the highest scores associated with a.-fold (95% confidence interval.77-fold to.75-fold) and 4.-fold (.84-fold to 5.63-fold) higher cancer incidence and cancer mortality, respectively. High chronic disease risk scores were associated with substantial years of life lost, and the highest scores were associated with 3.3 years of life lost in men and 5.9 years of life lost in women. The population attributable fractions of cancer incidence or cancer mortality from the eight chronic diseases and markers together were comparable to those from five major lifestyle factors combined (cancer incidence:.5% v 4.8%; cancer mortality: 38.9% v 39.7%). Among physically active (versus inactive) participants, the increased cancer risk associated with chronic diseases and markers was attenuated by 48% for cancer incidence and 7% for cancer mortality. CONCLUSIONS Chronic disease is an overlooked risk factor for cancer, as important as five major lifestyle factors combined. In this study, chronic diseases contributed to more than one fifth of the risk for incident cancer and more than one third of the risk for cancer death. Physical activity is associated with a nearly 4% reduction in the cancer risk associated with chronic diseases. Introduction Chronic diseases were responsible for 7% of deaths globally in 5, primarily from cancer, cardiovascular disease, diabetes, chronic kidney disease, and respiratory disease. Most notable were deaths due to cancer, which increased from 5.7 million in 99 to 8.8 million in 5, and the global cancer burden is expected to increase by 7% in the coming two decades. 3 4 Cancer and other chronic diseases share common risk factors, including aging and unhealthy lifestyles (eg, smoking, unhealthy diet, physical inactivity, obesity, and alcohol misuse). Certain noncancer chronic diseases may also predispose to cancer independent of their shared risk factors; however, current cancer prevention strategies focus on lifestyle risk factors and do not consider non-cancer chronic diseases as modifiable cancer risk factors, 5-7 probably because of the modest associations observed. Diabetes has been consistently associated with a modestly increased risk of cancer. 8- Accumulating evidence has also linked the risk of cancer with cardiovascular disease markers for example, blood pressure, -5 heart rate, 6 7 total cholesterol level, 8-3 chronic kidney disease, 4-9 and gouty arthritis marker (uric acid). 3-34 In addition, multiple studies the bmj BMJ 8;36:k34 doi:.36/bmj.k34
have implicated pulmonary disease in lung cancer, 35 but data on other cancer sites are lacking. These studies generally assessed chronic diseases or disease markers individually. As chronic diseases are typically clustered, it is necessary to study them simultaneously to elucidate their independent and joint impact on cancer risk, but few data are available on this topic. We have previously shown that physical activity could reduce all cause mortality, 36 but the role of physical activity in reducing chronic disease related cancer risk is unclear. Among 45 878 participants of the prospective MJ Cohort study, we investigated the independent and joint effect of several common chronic diseases or disease markers on cancer risk (cancer incidence and cancer mortality). Also, we compared the contribution of chronic diseases or disease markers to cancer risk with that of lifestyle factors. We further assessed whether physical activity could attenuate the cancer risk associated with chronic diseases or disease markers. Methods Study population and data collection The details of the MJ Cohort study population and data collection are reported elsewhere. 36-38 Between 996 and 7 the study members participated in a standardized fee-for-service comprehensive medical screening program run by a private firm (MJ Health Management Institution, Taiwan). Self paying participants come from all over Taiwan. Individuals paid by their employers can also participate in the program. There are four geographically representative MJ locations across Taiwan: northern (Taipei), north west (Taoyuan), central (Taichung), and southern (Kaohsiung) parts. The four locations used the same screening protocols and instruments, and data were centralized. The personal characteristics of the participants generally matched those of the general population, except that the cohort is slightly overrepresentative of adults aged less than 4. Participants completed a self administered questionnaire on medical history, lifestyle, and demographic information and underwent a series of medical tests (blood, urine, body measurements, functional tests, and physical examination). Exclusion criteria for the current study were age less than 8 years (n=4 989), a history of cancer at the time of recruitment (n=3574), and less than one year of follow-up (3 78). The final study cohort consisted of 45 878 participants (48.% men and 5.% women). The participants were encouraged to return for follow-up visits. Among the 45 878 participants, 77 43 (43.7%) had a second visit; the mean time from the baseline visit to the second visit was. years (SD.6 years). We classified the volume of leisure time physical activity the product of intensity (metabolic equivalent) and duration of exercise (hours), into five categories: inactive (<3.75 metabolic equivalent (MET) hours /week), low active (3.75-7.49 MET hours/week), medium active (7.5-6.49 MET hours/week), high active (6.5-5.49 MET hours/week), and very high active ( 5.5 MET hours/week), with the categories for medium active and above consisting of participants who met the current leisure time physical activity recommendation of 5 minutes a week of moderate intensity exercise or 75 minutes a week of vigorous intensity exercise. 36 39 Total fruit and vegetable intake (servings/day) was the sum of the intake of fruits, deep green vegetables, and light green vegetables. Chronic diseases and markers We selected five common chronic diseases for evaluation, which account for most of the disease burden worldwide: cardiovascular disease (as indicated by diastolic blood pressure and systolic blood pressure, total cholesterol level, and heart rate), diabetes (fasting blood glucose level), chronic kidney disease (dipstick proteinuria and estimated glomerular filtration rate), pulmonary disease (forced expiratory volume in one second and forced vital capacity), and gouty arthritis (uric acid). Box shows the diagnostic criteria or categorization of chronic diseases or markers used in this study. Follow-up for cancer Details of follow-up procedures have been reported 36 37 previously. Briefly, we obtained information on cancer incidence and vital status by linking study participants to the Taiwan cancer registry and Taiwan death file between 997 and 8 using the unique identification numbers assigned to Taiwanese residents. Cancer cases were identified from histological discharge forms and oncology reports and were classified according to ICD-9 (international classification of diseases, ninth revision) codes. During an average of 8.7 years (range.-.9 years) of follow-up, 966 587 person years were accumulated, and 973 cases of incident cancer and 3779 cancer related deaths were recorded. Statistical analysis The primary outcomes of interest were cancer incidence and cancer mortality overall, as well as cancer specific incidence and mortality. We calculated the time to event from the date of enrollment to the date of cancer incident or cancer related death, death due to causes other than cancer, or the end of cohort follow-up (3 December 8), whichever came first. We used Cox proportional hazards model to estimate hazard ratios and 95% confidence intervals, adjusting for age (continuous), age squared, sex (male or female), education (middle school or lower, high school, junior college, or college or higher), occupation (white collar, blue collar, self employed, housewife or house husband, or other), smoking status (never, former, or current), pack years of smoking (continuous), alcohol consumption status (never, ever), grams of alcohol/ day (continuous), body mass index (continuous), body mass index squared, physical activity (inactive, low active, medium active, high active, and very high active), and fruit and vegetable intake (continuous). doi:.36/bmj.k34 BMJ 8;36:k34 the bmj
Box : Diagnostic criteria or categorization of chronic diseases and markers Cardiovascular disease markers Blood pressure (Joint National Committee guidelines 4 ) : diastolic blood pressure <8 mm Hg and systolic blood pressure < mm Hg, not receiving medication, and no self reported hypertension Prehypertension: (diastolic blood pressure: 8-89 mm Hg or systolic blood pressure: -39 mm Hg), not receiving medication, and no self reported hypertension Hypertension: diastolic blood pressure 9 mm Hg or systolic blood pressure 4 mm Hg or receiving medication or self reported hypertension Total cholesterol (mmol/l): <4.5, 4.5-4.66, 4.67-5.8, 5.9-6., 6.; to convert SI unit of total cholesterol (mmol/l) to mg/dl multiply by 38.67 Heart rate (beats/min): <7, 7-79, 8-89, 9 Diabetes (WHO criteria 4 ) : fasting glucose level <6. mmol/l, not receiving medication, and no self reported diabetes; to convert SI unit of fasting glucose (mmol/l) to mg/dl multiply by 8. Prediabetes: fasting glucose level between 6. and 6.95 mmol/l, not receiving medication, and no self reported diabetes Diabetes: fasting glucose level 6.96 mmol/l or receiving medication or self reported diabetes Chronic kidney disease markers (National Kidney Foundation criteria 4 ) Proteinuria: no proteinuria, trace proteinuria, proteinuria ( +) Glomerular filtration rate (ml/min/.73 m ): 9, 6-89, <6 Pulmonary disease (Global Initiative for Chronic Obstructive Lung Disease (GOLD) criteria 43 ) : forced expiratory volume in one second (FEV )/forced vital capacity (FVC).7 and FEV 8% predicted Restrictive: FEV /FVC.7 and FEV <8% predicted Chronic obstructive pulmonary disease: FEV /FVC <.7 Gouty arthritis marker Uric acid (µmol/l): <97, 97-356, 357-45, 46-475, 476; to convert SI unit ofuric acid (µmol/l) to mg/dl divide by 59.48 We performed multiple imputation with iterations for missing data using Markov Chain Monte Carlo procedures, which assume that all the variables in the imputation model have a joint multivariate normal distribution, and analyses were performed on the dataset with imputed data. Since chronic diseases or conditions are typically clustered and the association of individual chronic disease or marker with cancer risk tends to be modest, we created two composite scores to investigate the joint effect of the eight chronic diseases and markers: one for risk of incident cancer and another for risk of cancer death. The composite score was calculated in four steps following the procedure by Sullivan et al 44 : ) run a multivariable Cox regression model that includes all potential confounders and the eight chronic diseases or markers to estimate the effect of each individual disease or marker independent of potential confounders and other chronic diseases or markers; ) calculate the individual risk point for each response category or level of a chronic disease or marker variable by dividing the respective regression coefficient with a single constant, which represents the regression coefficient for a one year increase in age in relation to risk of incident cancer or cancer death; 3) round the risk points to the nearest integers; and 4) calculate the composite score by summing the individual risk point for each chronic disease or marker across all eight chronic diseases and markers for each study participant. Therefore, the risk point (ie, weight) given to each condition was proportional to the strength of association (ie, hazard ratio or β coefficient from Cox regression model) with risk of incident cancer or cancer death. Supplementary table S shows more details on the development of composite chronic disease risk scores and two hypothetical examples. Using Chiang s life table method, years of life lost were the difference in life expectancy for those with and those without each condition or lifestyle risk factor. 45 The calculated life expectancy referred to the average remaining years of life expected for a 3 year old. To quantify the contribution of chronic diseases or markers to cancer incidence and cancer mortality, we calculated the population attributable fraction, which is the estimated proportional reduction in cancer incidence or cancer mortality that would occur if chronic diseases or markers were normal. We estimated the population attributable fraction for individual risk factor by the punafcc function in Stata, which was specifically developed for time to event studies. 46 We calculated the joint population attributable fraction of clusters of risk factors, which avoids double counting the overlap of multiple risk factors, using the formula shown in the illustration. 47 48 The relative reduction in risk of incident cancer and cancer death associated with chronic diseases or markers by physical activity was calculated as (hazard ratio inactive -hazard ratio active )/ (hazard ratio inactive -), 49 where hazard ratio inactive is the hazard ratio of chronic diseases or markers among those who were physically inactive, and hazard ratio active is the hazard ratio among those who were physically active. n Population attributable fraction = ( population attributable fraction r ), r= where population attributable fraction r = population attributable fraction for individual risk factor r, and n = total number of risk factors Patient involvement This study utilized data from the MJ Health Research Foundation, and details of patient and public involvement are available online (www.mjhrf.org/ main/index/en). Patients, service users, carers, and lay people were not involved in the design, recruitment, or conduct of this study, and outcome measures were not informed by patients priorities, experience, and preferences. The MJ Health Research Foundation will disseminate all key findings from this study on its website. Participants were thanked in the acknowledgment section. Results Individual associations of chronic diseases with cancer incidence and cancer mortality Table shows the selected characteristics of the 45 878 cohort participants at enrollment. A statistically significantly increased risk of incident cancer was observed for the eight diseases and markers the bmj BMJ 8;36:k34 doi:.36/bmj.k34 3
Table Baseline characteristics of the participants (n=45 878). Values are numbers (percentages) unless stated otherwise Characteristics Men (n=94 686) Women (n= 9) Mean (SD) age (years) 4.5 (3.8) 4.3 (3.8) Education: Middle school or lower 38 8 (9.5) 64 86 (3.7) High school 44 35 (.8) 5 97 (4.6) Junior college 43 4 (.3) 4 7 (9.3) College or higher 6 68 (3.) 44 7 (.) Missing 888 (4.3) 8983 (4.3) Occupation: White collar 9 447 (47.) 83 6 (39.3) Blue collar 48 533 (4.9) 6 634 (7.9) Self employed 7 84 (9.) 4 878 (7.) House wife, house husband 799 (.9) 65 6 (3.8) Other 3 78 (.9) 8 3 (8.7) Missing 988 (6.) 3 357 (6.3) Smoking status: Never 88 39 (45.4) 76 63 (83.3) Former 9 88 (.) 39 (.5) Current 75 85 (38.9) 836 (6.) Missing 68 (5.5) 8 64 (8.8) Mean (SD) pack years* 7. (7.5) 7.4 (.8) Alcohol consumption: Never 7 37 (6.3) 73 433 (8.) Former 85 (4.4) 68 (.) Current 56 93 (9.) 3 53 (6.4) Missing 87 (6.) 6 (.) Mean (SD) grams of alcohol/day 9.5 (.5) 6. (.8) Physical activity: Inactive 93 6 (48.) 5 73 (59.3) Low active 4 869 (.) 44 97 (.3) Medium active 3 94 (5.9) 4 8 (.4) High active 3 77 (7.) 996 (4.7) Very high active 3 56 (6.9) 6896 (3.3) Missing 4 (.) (.) Mean (SD) body mass index 3.8 (3.4). (3.6) Mean (SD) fruit and vegetable intake (portions/day) 5. (.8) 5. (.7) *Among ever smokers and missing for 564 (.4%) participants. Among ever drinkers and missing for 4 78 (3.6%) participants. Missing for 95 (.%) participants. Missing for 4 7 (3.5%) participants. individually, except blood pressure and pulmonary disease (fig ). Specifically, total cholesterol level was inversely associated with risk of incident cancer in a dose-response manner, with a 44% (hazard ratio.44, 95% confidence interval.33 to.56; P<.) increase in the lowest level compared with highest level (<4.5 v 6. mmol/l). In contrast, risk increased with heart rate, with 9% excess risk (.9,. to.8; P=.3) when the highest level of heart rate was compared with the lowest level ( 9 v <7 beats/min). Risk increased with severity of proteinuria: % (.,.4 to.; P=.4) with trace proteinuria and % (.,.9 to.35; P<.) with proteinuria. A U-shaped association was found between glomerular filtration rate and cancer incidence; compared with a glomerular filtration rate of 6-89 ml/min/.73 m, the risk for those with a low glomerular filtration rate increased by % (.,.4 to.8; P<.) and for those with a high glomerular filtration rate by % (.,.4 to.6; P<.). Risk increased by 5% (.5,.7 to.4; P<.) with low uric acid levels (<97 µmol/l) compared with a uric acid level between 46 and 475 µmol/l. All eight diseases or markers were statistically significantly associated with risk of cancer mortality (fig ), and the associations were generally stronger than those for cancer incidence. We conducted multiple sensitivity analyses. First, we conducted another round of multiple imputation with annul income, which was missing for 48.9% of the study population, and further adjusted for annual income. The results (see supplementary table S) were almost identical to those not adjusted for annual income (fig and fig ). Second, we stratified the analysis by years of follow-up (<5 v 5 years) and found similar results across the two stratums (see supplementary table S3). Third, the inverse association of total cholesterol with risk of incident cancer and cancer death was sustained after further exclusion of cancer cases developed within - years of follow-up (see supplementary table S4) and further adjustment for aspartate transaminase, alanine transaminase, α fetoprotein, and hepatitis B virus infection status (see supplementary table S5). Also, we conducted stratified analyses by smoking status (never versus ever, see supplementary table S6), alcohol consumption status (never versus ever, see supplementary table S7), body mass index (<5 v 5, see supplementary table S8), physical activity (inactive versus active, see supplementary table S9), and fruit and vegetable intake (low versus high, see supplementary table S), and associations generally were sustained within each stratum. Among 77 43 (43.7% of the overall study population of 45 878) participants who had a second visit, we investigated the associations between chronic diseases and markers at the second visit and risk of incident cancer and cancer death adjusted for updated covariates at the second visit (see supplementary table S), and the associations were similar to those observed with baseline measurements. We compared the host characteristics of those who had a second follow-up visit with those of the overall study population, and they were comparable (see supplementary table S). Joint associations of chronic diseases with cancer incidence and cancer mortality Figures and also show the fully adjusted hazard ratios (ie, when all chronic diseases or markers were included in one model in addition to the covariates) among 74 88 (67.7% of the overall study population of 45 878) participants who had complete data on all eight chronic diseases or markers, and the host characteristics were comparable to those of the overall study population (see supplementary table S). The findings, albeit attenuated for some chronic diseases and markers, were generally similar to those adjusted only for covariates. The individual risk points for each level of the eight chronic disease and marker variables also were presented, which ranged from zero to eight (figs and ). Total cholesterol level and proteinuria had the highest risk points. The composite chronic disease risk scores were positively associated with cancer incidence 4 doi:.36/bmj.k34 BMJ 8;36:k34 the bmj
Chronic diseases/markers Population Incidence Adjusted* hazard Cardiovascular disease markers Blood pressure Prehypertension Hypertension Total cholesterol (mmol/l) 6. 5.9 to 6. 4.67 to 5.8 4.5 to 4.66 <4.5 Heart rate (beats/min) <7 7 to 79 8 to 89 9 Diabetes Prediabetes Diabetes Chronic kidney disease markers Proteinuria Trace proteinuria Proteinuria size (%) 49 (5) 9 896 (3) 76 55 (9) 4 955 () 9 73 (8) 84 883 () 8 64 () 74 949 (9) 43 55 (36) 49 894 (38) 76 6 (9) 8 934 (7) 36 67 (9) 9 (5) 9 954 (5) 38 387 (9) 3 (6) 65 () 86 636 368 37 84 86 587 363 399 337 939 835 738 89 59 7784 7 376 ratio (95% CI). (.94 to.5).3 (.98 to.9).7 (. to.4).6 (.8 to.4).7 (.8 to.37).44 (.33 to.56). (.95 to.5).5 (.99 to.).9 (. to.8).6 (.98 to.4). (.3 to.8). (.4 to.). (.9 to.35) Glomerular filtration rate (ml/min/.73 m ) <6 6 to 89 9 Pulmonary disease Restrictive Chronic obstructive pulmonary disease 9 37 (5) 36 5 (59) 47 398 (37) 55 745 (75) 6 8 (8) 3 475 (7) 45 5988 85 597 44 58. (.4 to.8). (.4 to.6). (.97 to.8).99 (.93 to.6) Gouty arthritis marker: uric acid (µmol/l) 476 46 to 475 357 to 45 97 to 356 <97 48 863 () 57 5 (4) 84 984 () 97 933 (4) 4 73 (8) 48 355 5 6 335. (.93 to.9).4 (.97 to.).7 (. to.5).5 (.7 to.4) Adjusted* hazard ratio (95% CI) Fully adjusted Risk hazard ratio (95% CI) point.5 (.98 to.).7 (.99 to.5).3 (.4 to.).7 (.8 to.8).34 (. to.47).54 (.4 to.7).3 (.97 to.).7 (. to.5).7 (.97 to.8). (. to.).8 (.99 to.7). (. to.).9 (.4 to.36). (.4 to.).9 (. to.8).99 (.94 to.6).96 (.88 to.4).97 (.89 to.7). (.9 to.9).4 (.96 to.4). (. to.) 3 5 7 3.5 Fig Chronic diseases and markers and risk of incident cancer. *Adjusted for age (continuous), age squared, sex, education (middle school or lower, high school, junior college, or college or higher), occupation (white collar, blue collar, self employed, housewife or house husband, or other), smoking status (never, former, or current), pack years of smoking (continuous), alcohol consumption status (never, ever), grams of alcohol/day (continuous), body mass index (continuous), body mass index squared, physical activity (inactive, low active, medium active, high active, and very high active), and fruit and vegetable intake (continuous). All chronic diseases and markers were simultaneously included in the model in addition to the covariates (fig 3) and cancer mortality (fig 3) in a dose-response manner (P<. for trend for both) in the overall population (red broken lines in figure). Compared with participants scoring, those who scored to 4, 5 to 8, 9 to, or had an increased hazard ratio for cancer incidence of.3,.36,.6, or. (fig 3), respectively. Similar but stronger associations were observed for cancer mortality; compared with participants scoring, those who scored 3 to 6, 7 to, to 4, or 5 had an increased hazard ratio of.6,.3, 3.4, or 4. for cancer mortality (fig 3), respectively. Also, we applied the risk scores developed at baseline to chronic disease or marker measurements at the second visit among the 77 43 participants who had a second visit, and a dose-response relation was also seen for the analysis using patients with data from a second visit (see supplementary table S3). Every increment of five chronic disease risk scores was associated with a 35% (hazard ratio.35,.8 to.4; P<.) increase in overall risk of incident cancer and 5% (.5,.4 to.58; P<.) increase in overall risk of cancer death (fig 4). For specific cancers, the highest risk of incident cancer was observed for liver cancer followed by the bmj BMJ 8;36:k34 doi:.36/bmj.k34 5
Chronic diseases/markers Population Incidence Adjusted* hazard Cardiovascular disease markers size (%) ratio (95% CI) Blood pressure Prehypertension Hypertension Total cholesterol (mmol/l) 49 (5) 9 896 (3) 76 55 (9) 889 5 83.8 (.98 to.8). (. to.3) 6. 5.9 to 6. 4.67 to 5.8 4.5 to 4.66 <4.5 Heart rate (beats/min) 4 955 () 9 73 (8) 84 883 () 8 64 () 74 949 (9) 549 33 74 66 57.5 (.94 to.6).5 (.3 to.9).38 (.3 to.54).64 (.45 to.85) <7 7 to 79 8 to 89 9 Diabetes 43 55 (36) 49 894 (38) 76 6 (9) 8 934 (7) 86 36 78 39.3 (.95 to.). (.3 to.3).35 (. to.5) Prediabetes Diabetes Chronic kidney disease markers 36 67 (9) 9 (5) 9 954 (5) 83 356 589.7 (.96 to.).4 (.9 to.55) Proteinuria Trace proteinuria Proteinuria 38 387 (9) 3 (6) 65 () 37 374.35 (. to.5).7 (.48 to.95) Glomerular filtration rate (ml/min/.73 m ) <6 6 to 89 9 Pulmonary disease 9 37 (5) 36 5 (59) 47 398 (37) 798 4 555. (. to.33).8 (.98 to.9) Restrictive Chronic obstructive pulmonary disease 55 745 (75) 6 8 (8) 3 475 (7) 93 7 55.5 (.6 to.3).9 (.99 to.) Gouty arthritis marker: uric acid (µmol/l) 476 46 to 475 357 to 45 97 to 356 <97 48 863 () 57 5 (4) 84 984 () 97 933 (4) 4 73 (8) 69 67 835 877 846.8 (.96 to.).99 (.89 to.).6 (.95 to.7). (.9 to.36) Adjusted* hazard ratio (95% CI) Fully adjusted Risk hazard ratio (95% CI) point.5 (.3 to.9). (.8 to.36).8 (.4 to.33).3 (.7 to.4).53 (.33 to.77).85 (.6 to.5).6 (.96 to.6).4 (. to.8).8 (. to.37). (.96 to.7).3 (.8 to.49).9 (.3 to.47).53 (.8 to.8). (.7 to.33). (.9 to.5). (. to.).6 (.94 to.). (.87 to.5).98 (.86 to.).6 (.93 to.).7 (. to.34) 3 5 8 3 3 5.5 Fig Chronic diseases and markers and risk of cancer death. *Adjusted for age (continuous), age squared, sex, education (middle school or lower, high school, junior college, or college or higher), occupation (white collar, blue collar, self employed, housewife or house husband, or other), smoking status (never, former, or current), pack years of smoking (continuous), alcohol consumption status (never, ever), grams of alcohol/day (continuous), body mass index (continuous), body mass index squared, physical activity (inactive, low active, medium active, high active, and very high active), and fruit and vegetable intake (continuous). All chronic diseases and markers were simultaneously included in the model in addition to the covariates bladder cancer, kidney cancer, oral cancer, and stomach cancer; the highest risk of cancer death was observed for bladder cancer followed by liver cancer, kidney cancer, oral cancer, and colorectal cancer. Life expectancy Higher chronic disease risk scores were associated with greater years of life lost, with the highest scores associated with 3.3 years of life lost in men and 5.9 years of life lost in women (fig 5). Among men, the greatest years of life lost was associated with heart rate 9 beats/min (7.4 years) followed by trace proteinuria or proteinuria (6.6 years), pulmonary disease (5.8 years), diabetes (5. years), glomerular filtration rate <6 ml/ min/.73 m (3.3 years), hypertension (3. years), total cholesterol <4.5 mmol/l (.6 years), and uric acid <97 µmol/l (.5 years). Among women, the greatest years of life lost was associated with trace proteinuria or proteinuria (6.9 years) followed by diabetes (5.9 years), glomerular filtration rate <6 ml/min/.73 m (5.7 years), heart rate 9 beats/ min (5.4 years), total cholesterol <4.5 mmol/l (4.6 6 doi:.36/bmj.k34 BMJ 8;36:k34 the bmj
Hazard ratio Cancer incidence 8 Physically inactive Overall Physically active 4 to 4 5 to 8 9 to Chronic disease risk score Physically inactive Overall Physically active Risk reduction by physical activity (%) Hazard ratio Cancer mortality 8 4.8 (.9 to.56).3 (.94 to.34).8 (.86 to.36) 54.49 (.4 to.96).36 (.4 to.6).6 (. to.59) 47.79 (.35 to.37).6 (.35 to.94).49 (.7 to.89) years), hypertension (4. years), and pulmonary disease (3.7 years). Uric acid <97 µmol/l was associated with a gain of.8 years of life in women. For the lifestyle factors, ever smoking was related to the greatest years of life lost in both men (4.3 years) and women (4.8 years). 38.7 (.96 to 3.76). (.77 to.75).79 (.3 to.44) 3 to 6 7 to to 4 5 Physically inactive Overall Physically active Risk reduction by physical activity (%).65 (. to.65).6 (.7 to.8).56 (.3 to.35) 4.3 (.44 to 3.7).3 (.56 to.9).99 (.3 to 3.) 4 54 Chronic disease risk score 3.5 (.5 to 5.7) 3.4 (. to 4.).7 (.76 to 4.6) 3 4.83 (.9 to 8.4) 4. (.84 to 5.63) 3.33 (. to 5.3) Fig 3 Chronic disease risk score and risk of incident cancer and cancer death overall and stratified by physical activity. Numbers at bottom of graphs represent adjusted hazard ratios (95% confidence intervals) adjusted for age (continuous), age squared, sex, education (middle school or lower, high school, junior college, or college or higher), occupation (white collar, blue collar, self employed, housewife or house husband, or other), smoking status (never, former, or current), pack years of smoking (continuous), alcohol consumption status (never, ever), grams of alcohol/ day (continuous), body mass index (continuous), body mass index squared, physical activity (inactive, low active, medium active, high active, and very high active), and fruit and vegetable intake (continuous), wherever appropriate. Physically inactive: <3.75 metabolic equivalent (MET) hours/week; physically active: 3.75 MET hours/week. The relative reduction in risk of incident cancer and cancer death associated with chronic diseases or disease markers by physical activity was calculated as (hazard ratio inactive - hazard ratio active )/(hazard ratio inactive -), where hazard ratio inactive is the hazard ratio of chronic diseases/markers among those who were physically inactive, and hazard ratio active is the hazard ratio among those who were physically active 39 Population attributable fraction of cancer incidence and cancer mortality Among the eight chronic diseases or markers, low total cholesterol level contributed the most and accounted for 5.7% of cancer incidence (fig 6). The three cardiovascular disease markers (low total cholesterol level, hypertension or prehypertension, and high heart rate) together accounted for.4%, chronic kidney disease markers (trace proteinuria or proteinuria and abnormal glomerular filtration rate combined) for 4.4%, abnormal uric acid for 3.%, diabetes or prediabetes for.7%, and pulmonary disease for %. The total contribution to cancer incidence from the eight chronic diseases or markers (population attributable fraction.5%) was close to that of five major lifestyle factors (4.8%), including ever smoking, insufficient physical activity, insufficient fruit and vegetable intake, ever alcohol consumption, and non-ideal body mass index. The total contribution to cancer mortality (fig 7) from the eight chronic diseases or markers (population attributable fraction 38.9%) was also close to that of five major lifestyle factors (39.7%). Physical activity for reduction of cancer incidence and cancer mortality associated with chronic diseases We assessed whether physical activity could reduce the risk of incident cancer or cancer death associated with chronic diseases and markers (as indicated by the chronic disease risk scores). The positive associations of chronic disease risk scores with cancer incidence and cancer mortality were weaker among those who were physically active compared with those who were physically inactive (fig 3). Physical activity attenuated the increased hazards by 38% to 54% (an average of 48%) for cancer incidence and 4% to 39% (an average of 7%) for cancer mortality. Discussion In this large cohort study, we found that cardiovascular disease markers, diabetes, chronic kidney disease markers, pulmonary disease, and gouty arthritis marker were individually associated with risk of incident cancer or cancer death. Higher chronic disease risk scores based on these diseases or markers were linked with an increased risk of incident cancer and cancer death in a dose-response manner, with the highest level associated with a more than twofold increase in risk of incident cancer and a fourfold increase in risk of cancer death. Jointly, they accounted for more than one fifth of all incident cancers and more than one third of all cancer deaths, which was comparable to the contribution of five major lifestyle risk factors combined. Physical activity was associated with a nearly 4% reduction in the excess risks of incident cancer and cancer death associated with chronic diseases and markers. Chronic diseases are not targeted in current cancer prevention strategies 5-7 ; nevertheless, our study revealed a previously overlooked yet substantial impact the bmj BMJ 8;36:k34 doi:.36/bmj.k34 7
Cancer incidence Specific cancer Liver cancer Bladder cancer Kidney cancer Oral cancer Stomach cancer Lung cancer Breast cancer Pancreatic cancer Colorectal cancer Prostate cancer All cancer Cancer mortality Specific cancer Bladder cancer Liver cancer Kidney cancer Oral cancer Colorectal cancer Breast cancer Prostate cancer Stomach cancer Lung cancer Pancreatic cancer All cancer No of cases 78 7 33 544 467 943 97 4 3 476 7969 56 834 86 8 343 6 98 5 696 4 3396 Adjusted* hazard ratio (95% CI).5 4 Adjusted* hazard ratio (95% CI).59 (.3 to.9).7 (.8 to.3).55 (.8 to.3).36 (. to.64).7 (.5 to.54).4 (.9 to.). (.89 to.9). (.7 to.44). (.88 to.4). (.8 to.).35 (.8 to.4).57 (.67 to 3.97).6 (.94 to.4).67 (. to.3).54 (. to.97).43 (. to.69).4 (. to.95).36 (.98 to.89).3 (.8 to.6).4 (. to.9).4 (.77 to.4).5 (.4 to.58) Fig 4 Adjusted hazard ratios associated every increment of five chronic disease risk scores for cancer incidence and cancer mortality of overall cancers and specific cancers. *Hazard ratios were adjusted for age (continuous), age squared, sex, education (middle school or lower, high school, junior college, or college or higher), occupation (white collar, blue collar, self employed, housewife or house husband, or other), smoking status (never, former, or current), pack years of smoking (continuous), alcohol consumption status (never, ever), grams of alcohol/day (continuous), body mass index (continuous), body mass index squared, physical activity (inactive, low active, medium active, high active, and very high active), and fruit and vegetable intake (continuous) of chronic diseases on cancer risk. To quantify the joint contribution of the eight chronic diseases or markers to cancer risk and to estimate the proportional reduction in cancer risk that would occur if the eight diseases or markers were reduced to ideal levels, we calculated the population attributable fractions of cancer incidence and cancer mortality associated with the eight chronic diseases and markers. We found that they jointly contributed to more than one fifth (population attributable fraction.5%) of cancer incidence and more than one third of cancer mortality (38.9%), equally important as five major lifestyle factors, including ever smoking, insufficient physical activity, insufficient fruit and vegetable intake, ever alcohol consumption, and obesity. To date, three studies have estimated the population attributable fraction for diabetes in relation to overall cancer or specific cancers, which ranged from.4% for overall cancer incidence to 7.3% for pancreatic cancer mortality. 5-53 Population attributable fraction estimates for other diseases and markers are not available. Even if they were available, the joint contribution, by simply summing the population attributable fraction estimate of each disease or marker from individual studies, could be overestimated owing to the correlations among the diseases and markers. In our study, we weighted eight chronic diseases or markers into chronic disease risk scores and found that those with higher risk scores were at substantially increased risk of incident cancer and cancer death in a dose-response manner. Among the eight diseases and markers, total cholesterol level and proteinuria carried the most weight in the computation of the overall chronic disease risk scores, suggesting that these two markers are stronger predictors of cancer risk than are the other diseases or markers. Also, we found that the risks of liver, bladder, kidney, stomach, oral, and colorectal cancers were increased with increased chronic disease risk scores, suggesting that chronic diseases or underlying biological alterations may play an important role in the cause of these specific cancers. The association between total cholesterol level and cancer risk has been controversial. 54 Based on the relatively well established association between high cholesterol levels and cardiovascular disease risk, we may extrapolate that a high cholesterol level is also linked with cancer risk. However, the association between cholesterol level and cancer risk is less established. Our study showed that those with low cholesterol levels are at higher risk of cancer. Similar findings were also observed in two Korean cohorts 8 3 and a Japanese cohort, 9 and in white populations. - More evidence was needed to clarify whether the inverse association was causal or related to undiagnosed cancer or liver disease, which can lower total cholesterol levels. In our study, the inverse association was sustained after exclusion of cancer cases developed within years of follow-up (see supplementary table S4) and after further adjustment for aspartate transaminase, alanine transaminase, α fetoprotein, and hepatitis B virus infection status (see supplementary table S5). Although we were unable to completely rule out the possibility that a low total cholesterol level is just a marker of risk, the doseresponse relation, the exclusion of cancers during recent follow-up, and further adjustment for liver enzymes, tumor marker, and liver infection minimize the likelihood of reverse causation and lend support for causality. Our observation of an increased risk associated with low glomerular filtration rate is consistent with previous findings. 5-9 Our results also suggested that a high glomerular filtration rate ( 9 ml/ min/.73 m ) was associated with an increased risk of incident cancer and cancer death, consistent with a previous finding of a U-shaped association between glomerular filtration rate and cancer. 5 We also found that cancer incidence and cancer mortality increased substantially with increasing severity of proteinuria in a dose-response manner, which was consistent with the findings from a previous study of overall cancer mortality. 55 This positive association remained after further adjustment for glomerular filtration rate 8 doi:.36/bmj.k34 BMJ 8;36:k34 the bmj
Category Chronic disease risk score High ( 5) Medium-high (-4) Medium (7-) Medium-low (3-6) Individual chronic diseases/markers Heart rate 9 beats/min Trace proteinuria or proteinuria Pulmonary disease Diabetes Glomerular filtration rate <6 ml/min/.73m Hypertension Total cholesterol <4.5 mmol/l Uric acid <97 µmol/l Lifestyle factors Ever smoking Physical inactivity Ever alcohol consumption Low fruit/vegetable intake Obesity Men Category Women Chronic disease risk score High ( 5) Medium-high (-4) Medium (7-) Medium-low (3-6) Individual chronic diseases/markers Trace proteinuria or proteinuria Diabetes Glomerular filtration rate <6 ml/min/.73m Heart rate 9 beats/min Total cholesterol <4.5 mmol/l Hypertension Pulmonary disease Uric acid <97 µmol/l Lifestyle factors Ever smoking Physical inactivity Obesity Ever alcohol consumption Low fruit/vegetable intake -4-4 6 8 4 6 Years of life lost Fig 5 Years of life lost associated with chronic disease risk score, individual chronic disease or marker, and lifestyle risk factors among men and women. Physically inactivity refers to <3.75 metabolic equivalent hours/week, and low fruit and vegetable intake refers to < portions/day and other chronic diseases and markers, suggesting that proteinuria is independently associated with cancer risk. In our previous study, we showed that exercise for as little as 5 minutes a day was associated with a % reduced risk of cancer mortality and that every additional 5 minutes of daily exercise beyond this minimum amount was associated with an additional % reduction. 36 In the present study, we further found that physical activity was associated with a 48% reduction in risk of incident cancer and a 7% reduction in risk of cancer death related to chronic diseases and markers. However, since physical activity was self reported and might be associated with other unmeasured health related behaviors, more studies are warranted to explore how exercise might modify chronic disease related cancer risk independent of other factors. Implications of findings These findings have important implications for cancer prevention. Current global cancer prevention strategies usually focus on modifying lifestyle risk factors. In our study, more than one fifth of incident cancers and the bmj BMJ 8;36:k34 doi:.36/bmj.k34 9
Population attributable fraction (%) Chronic kidney disease markers Total (4.4%) Cardiovascular disease markers Total (.4%) Pulmonary disease (%) Diabetes or prediabetes (.7%) Abnormal uric acid level (3.%) Trace proteinuria or proteinuria (.5%) Abnormal glomerular filtration rate (3.3%) High heart rate (3.%) Hypertension or prehypertension (4.%) Low total cholesterol level (5.7%) Chronic diseases/markers Total (.5%) Non-ideal body mass index (.6%) Alcohol consumption (4.%) Insufficient physical activity (5.7%) Insufficient fruit/vegetable intake (5.9%) Smoking (.3%) Lifestyle risk factors Total (4.8%) Fig 6 Population attributable fractions of cancer incidence due to chronic diseases or markers and lifestyle risk factors. Abnormal glomerular filtration rate=<6 or 9 ml/min/.73 m ; abnormal uric acid level=<46 or 476 µmol/l; high heart rate= 7 beats/min; low total cholesterol level=<4.5 or 4.5-4.66 mmol/l; smoking=ever smoking; insufficient physical activity refers to levels that do not meet current leisure time physical activity recommendation of 5 minutes a week of moderate intensity or 75 minutes a week of vigorous intensity (ie, <7.5 metabolic equivalent hours/ week) 36 39 ; insufficient fruit/vegetable intake refers to <5 portions/day recommended by the Word Health Organization 5 ; alcohol consumption refers to ever alcohol consumption; non-ideal body mass index refers to body mass index of more than.9 kg/m, which was the mean body mass index in the normal body mass index (8.5-4.9) category in this study population Population attributable fraction (%) Chronic kidney disease markers Total (7.9%) Cardiovascular disease markers Total (4.7%) more than one third of cancer deaths were attributable to the eight chronic diseases or markers assuming the observed associations are causal, and this was equal to the combined contribution of five lifestyle risk factors. Therefore, a major player will be missed if future cancer prevention strategies do not target non-cancer chronic diseases. At the same time, these findings have important implications for the management of noncancer chronic diseases. Although chronic diseases are responsible for most deaths globally, ineffective management of such diseases in primary care is a global problem and leads to poor health outcomes and increased healthcare costs. 56 Our results showed that chronic diseases and markers were associated with a substantial reduction in life span that is more Pulmonary disease (3.7%) Abnormal uric acid level (4.%) Abnormal glomerular filtration rate (3.7%) Trace proteinuria or proteinuria (4.3%) Diabetes or prediabetes (4.8%) High heart rate (6.%) Low total cholesterol level (8.7%) Hypertension or prehypertension (.%) Chronic diseases/markers Total (38.9%) Non-ideal body mass index (.9%) Alcohol consumption (5.7%) Insufficient fruit/vegetable intake (8.8%) Insufficient physical activity (.3%) Smoking (8.6%) Lifestyle risk factors Total (39.7%) Fig 7 Population attributable fractions of cancer mortality due to chronic diseases or markers and lifestyle risk factors. Abnormal glomerular filtration rate=<6 or 9 ml/ min/.73 m ; abnormal uric acid level=<46 or 476 µmol/l; high heart rate= 7 beats/ min; low total cholesterol level=<4.5 or 4.5-4.66 mmol/l; smoking=ever smoking; insufficient physical activity refers to levels that do not meet current leisure time physical activity recommendation of 5 minutes a week of moderate intensity or 75 minutes a week of vigorous intensity (ie, <7.5 metabolic equivalent hours/week) 36 39 ; insufficient fruit/vegetable intake refers to <5 portions/day recommended by the Word Health Organization 5 ; alcohol consumption refers to ever alcohol consumption; non-ideal body mass index refers to body mass index less than or more than 5.6 kg/m, which was associated with the lowest risk of cancer mortality in this study intuitive and easier to communicate than commonly used hazard ratios. In addition, our study revealed an overlooked link between chronic diseases and markers and risk of cancer, which is the disease most feared by people. 57 58 Therefore, recognizing the substantial reduction in life span and increase in cancer risk associated with non-cancer chronic diseases could be used as a teachable moment to stimulate motivation for better management of such diseases. Strengths and weaknesses of this study Our study has several strengths. First, we examined several major chronic diseases and markers simultaneously, which allowed the estimate of their joint effects on cancer risk. Second, the chronic diseases were diagnosed on the basis of quantitative medical examinations, which allowed for the assessment of the dose-response relation and reduced measurement errors owing to self report. Third, because Taiwan has a central population based death file and a cancer registry, few people were lost to follow-up. Fourth, the increased risk of cancer associated with chronic diseases could result from the shared risk factors between chronic diseases and cancer. For example, physically inactive participants are more likely to have chronic diseases or abnormal disease markers and are also at higher risk of cancer. In our study, we were able to adjust for the major shared risk factors in all statistical models. We also conducted stratified analyses by those risk factors, and the stratified results suggested that the associations between chronic diseases and cancer risks generally remained within each stratum. However, we could not exclude the possibility that some of the observed cancer risk is still due to residual confounding from misclassification of the adjusted confounders, which were self reported or related to unmeasured lifestyle factors that can lead to both the chronic diseases and the cancer. Fifth, we mutually adjusted for the eight chronic diseases or markers, which allowed us to estimate the association between individual chronic diseases and markers and cancer risk independent of other correlated chronic diseases and markers. Finally, we incorporated chronic disease and marker measurements at both baseline and a second visit, which showed similar associations with cancer risk. Our study had several potential limitations. First, it was an observational study; therefore, the observed associations might not be causal. However, the strength of association, dose-response relation, consistency with previous studies, temporality, and biological plausibility lend support for causality. Second, although the observed associations are expected to be generalizable to other populations, the generalizability of the population attributable fraction estimates also depends on the population specific prevalence of chronic diseases and markers and lifestyle risk factors. Third, we only included the major non-cancer chronic diseases and markers that represent the majority of chronic disease burden, so the total contribution of non-cancer chronic diseases would be greater if doi:.36/bmj.k34 BMJ 8;36:k34 the bmj